The Bazel Query Reference
- Examples
- Tokens: The Lexical Syntax
- Bazel Query Language Concepts
- Expressions: Syntax and Semantics of the Grammar
- Functions
- Output Formats
When you use bazel query
to analyze build
dependencies, you use a little language, the Bazel Query
Language. This document is the reference manual for that
language. This document also describes the output
formats bazel query
supports.
If you were looking for a how-to, please see the Bazel Query How-To.
bazel cquery
Traditional bazel query runs on the post-loading phase target graph and therefore has no concept of configurations and their related concepts. Notably, this means it does not correctly resolve select statements and rather returns all possible resolutions of selects. A newer query environment, cquery, properly handles configurations but doesn't provide all of the functionality of this original query. For more information, see the Bazel cquery reference.
Examples
How do people use bazel query
? Here are typical examples:
Why does the //foo
tree depend on //bar/baz
?
Show a path:
somepath(foo/..., //bar/baz:all)
What C++ libraries do all the foo
tests depend on that
the foo_bin
target does not?
kind("cc_library", deps(kind(".*test rule", foo/...)) except deps(//foo:foo_bin))
Tokens: The Lexical Syntax
Expressions in the query language are composed of the following tokens:
-
Keywords, such as
let
. Keywords are the reserved words of the language, and each of them is described below. The complete set of keywords is:except
in
intersect
let
set
union
-
Words, such as
foo/...
or".*test rule"
or//bar/baz:all
. If a character sequence is "quoted" (begins and ends with a single-quote'
, or begins and ends with a double-quote"
), it is a word. If a character sequence is not quoted, it may still be parsed as a word. Unquoted words are sequences of characters drawn from the set of alphabet characters, numerals, slash/
, hyphen-
, underscore_
, star*
, and period.
. Unquoted words may not start with a hyphen or period.We chose this syntax so that quote marks aren't needed in most cases. The (unusual)
".*test rule"
example needs quotes: it starts with a period and contains a space. Quoting"cc_library"
is unnecessary but harmless.Quoting is necessary when writing scripts that construct Bazel query expressions from user-supplied values.
//foo:bar+wiz # WRONG: scanned as //foo:bar + wiz. //foo:bar=wiz # WRONG: scanned as //foo:bar = wiz. "//foo:bar+wiz" # ok. "//foo:bar=wiz" # ok.
Note that this quoting is in addition to any quoting that may be required by your shell. e.g.
bazel query ' "//foo:bar=wiz" ' # single-quotes for shell, double-quotes for Bazel.
Keywords, when quoted, are treated as ordinary words, thus
some
is a keyword but"some"
is a word. Bothfoo
and"foo"
are words. - Punctuation, such as parens
()
, period.
and comma,
, etc. Words containing punctuation (other than the exceptions listed above) must be quoted.
Whitespace characters outside of a quoted word are ignored.
Bazel Query Language Concepts
The Bazel query language is a language of expressions. Every expression evaluates to a partially-ordered set of targets, or equivalently, a graph (DAG) of targets. This is the only datatype.
In some expressions, the partial order of the graph is not interesting; In this case, we call the values "sets". In cases where the partial order of elements is significant, we call values "graphs". Note that both terms refer to the same datatype, but merely emphasize different aspects of it.
Cycles in the dependency graph
Build dependency graphs should be acyclic. The algorithms used by the query language are intended for use in acyclic graphs, but are robust against cycles. The details of how cycles are treated are not specified and should not be relied upon.
Implicit dependencies
In addition to build dependencies that are defined explicitly in BUILD files,
Bazel adds additional implicit dependencies to rules. For example
every Java rule implicitly depends on the JavaBuilder. Implicit dependencies
are established using attributes that start with $
and they
cannot be overridden in BUILD files.
Per default bazel query
takes implicit dependencies into account
when computing the query result. This behavior can be changed with
the --[no]implicit_deps
option.
Soundness
Bazel query language expressions operate over the build dependency graph, which is the graph implicitly defined by all rule declarations in all BUILD files. It is important to understand that this graph is somewhat abstract, and does not constitute a complete description of how to perform all the steps of a build. In order to perform a build, a configuration is required too; see the configurations section of the User's Guide for more detail.
The result of evaluating an expression in the Bazel query language is true for all configurations, which means that it may be a conservative over-approximation, and not exactly precise. If you use the query tool to compute the set of all source files needed during a build, it may report more than are actually necessary because, for example, the query tool will include all the files needed to support message translation, even though you don't intend to use that feature in your build.
On the preservation of graph order
Operations preserve any ordering
constraints inherited from their subexpressions. You can think of
this as "the law of conservation of partial order". Consider an
example: if you issue a query to determine the transitive closure of
dependencies of a particular target, the resulting set is ordered
according to the dependency graph. If you filter that set to
include only the targets of file
kind, the same
transitive partial ordering relation holds between every
pair of targets in the resulting subset—even though none of
these pairs is actually directly connected in the original graph.
(There are no file–file edges in the build dependency graph).
However, while all operators preserve order, some operations, such as the set operations don't introduce any ordering constraints of their own. Consider this expression:
deps(x) union y
The order of the final result set is guaranteed to preserve all the
ordering constraints of its subexpressions, namely, that all the
transitive dependencies of x
are correctly ordered with
respect to each other. However, the query guarantees nothing about
the ordering of the targets in y
, nor about the
ordering of the targets in deps(x)
relative to those in
y
(except for those targets in
y
that also happen to be in deps(x)
).
Operators that introduce ordering constraints include:
allpaths
,
deps
,
rdeps
,
somepath
,
and the target pattern wildcards
package:*
,
dir/...
, etc.
Sky Query
Query has two different implementations, with slightly different features. The alternative one is
called "Sky Query", and is activated by passing the following two flags:
--universe_scope
and --order_output=no
.
--universe_scope=<target_pattern1>,...,<target_patternN>
tells query to
preload the transitive closure of the target pattern specified by the target patterns, which can
be both additive and subtractive. All queries are then evaluated in this "scope". In particular,
the allrdeps
and
rbuildfiles
operators only return results from this scope.
Sky Query has some advantages and disadvantages compared to the default query. The main
disadvantage is that it cannot order its output according to graph order, and thus certain
output formats are forbidden. Its advantages are that it provides
two operators (allrdeps
and
rbuildfiles
) that are not available in the default query.
As well, Sky Query does its work by introspecting the
Skyframe graph, rather than creating a new
graph, which is what the default implementation does. Thus, there are some circumstances in which
it is faster and uses less memory.
Expressions: Syntax and Semantics of the Grammar
This is the grammar of the Bazel query language, expressed in EBNF notation:
expr ::= word | let name = expr in expr | (expr) | expr intersect expr | expr ^ expr | expr union expr | expr + expr | expr except expr | expr - expr | set(word *) | word '(' int | word | expr ... ')'
We will examine each of the productions of this grammar in order.
Target patterns
expr ::= word
Syntactically, a target pattern is just a word. It
is interpreted as an (unordered) set of targets. The simplest
target pattern is a label,
which identifies a single target (file or rule). For example, the
target pattern //foo:bar
evaluates to a set
containing one element, the target, the bar
rule.
Target patterns generalize labels to include wildcards over packages
and targets. For example, foo/...:all
(or
just foo/...
) is a target pattern that evaluates to a
set containing all rules in every package recursively
beneath the foo
directory;
bar/baz:all
is a target pattern that
evaluates to a set containing all the rules in the
bar/baz
package, but not its subpackages.
Similarly, foo/...:*
is a target pattern that evaluates
to a set containing all targets (rules and files) in
every package recursively beneath the foo
directory;
bar/baz:*
evaluates to a set containing
all the targets in the
bar/baz
package, but not its subpackages.
Because the :*
wildcard matches files as well as rules,
it is often more useful than :all
for queries.
Conversely, the :all
wildcard (implicit in target
patterns like foo/...
) is typically more useful for
builds.
bazel query
target patterns work the same as
bazel build
build targets do;
refer to Target Patterns
in the Bazel User Manual for further details, or type bazel
help target-syntax
.
Target patterns may evaluate to a singleton set (in the case of a
label), to a set containing many elements (as in the case of
foo/...
, which has thousands of elements) or to the
empty set, if the target pattern matches no targets.
All nodes in the result of a target pattern expression are correctly
ordered relative to each other according to the dependency relation.
So, the result of foo:*
is not just the set of targets
in package foo
, it is also the graph over
those targets. (No guarantees are made about the relative ordering
of the result nodes against other nodes.) See the section
on graph order for more details.
Variables
expr ::= let name = expr1 in expr2 | $name
The Bazel query language allows definitions of and references to
variables. The
result of evaluation of a let
expression is the same as
that of expr2, with all free occurrences of
variable name replaced by the value of
expr1.
For example, let v = foo/... in allpaths($v, //common)
intersect $v
is equivalent to the allpaths(foo/...,
//common) intersect foo/...
.
An occurrence of a variable reference name
other than in
an enclosing let name = ...
expression is an
error. In other words, toplevel query expressions cannot have free
variables.
In the above grammar productions, name
is like
word, but with the additional constraint that it be a legal
identifier in the C programming language. References to the variable
must be prepended with the "$" character.
Each let
expression defines only a single variable,
but you can nest them.
(Both target patterns and variable references consist of just a single token, a word, creating a syntactic ambiguity. However, there is no semantic ambiguity, because the subset of words that are legal variable names is disjoint from the subset of words that are legal target patterns.)
(Technically speaking, let
expressions do not increase
the expressiveness of the query language: any query expressible in
the language can also be expressed without them. However, they
improve the conciseness of many queries, and may also lead to more
efficient query evaluation.)
Parenthesized expressions
expr ::= (expr)
Parentheses associate subexpressions to force an order of evaluation. A parenthesized expression evaluates to the value of its argument.
Algebraic set operations: intersection, union, set difference
expr ::= expr intersect expr | expr ^ expr | expr union expr | expr + expr | expr except expr | expr - expr
These three operators compute the usual set operations over their
arguments. Each operator has two forms, a nominal form such
as intersect
and a symbolic form such
as ^
. Both forms are equivalent;
the symbolic forms are quicker to type. (For clarity, the rest of
this manual uses the nominal forms.) For example,
foo/... except foo/bar/...evaluates to the set of targets that match
foo/...
but not
foo/bar/...
. Equivalently:
foo/... - foo/bar/...The
intersect
(^
)
and union
(+
) operations are commutative
(symmetric); except
(-
) is
asymmetric. The parser treats all three operators as
left-associative and of equal precedence, so you might want parentheses.
For example, the first two of these expressions are
equivalent, but the third is not:
x intersect y union z (x intersect y) union z x intersect (y union z)
(We strongly recommend that you use parentheses where there is any danger of ambiguity in reading a query expression.)
Read targets from an external source: set
expr ::= set(word *)
The set(a b c ...)
operator computes the union of a set of zero or
more target patterns, separated by
whitespace (no commas).
In conjunction with the Bourne shell's $(...)
feature, set()
provides a means of saving the results
of one query in a regular text file, manipulating that text file
using other programs (e.g. standard UNIX shell tools), and then
introducing the result back into the query tool as a value for
further processing. For example:
bazel query deps(//my:target) --output=label | grep ... | sed ... | awk ... > foo bazel query "kind(cc_binary, set($(<foo)))"
In the next example, kind(cc_library,
deps(//some_dir/foo:main, 5))
is effectively computed
by filtering on the maxrank
values using
an awk
program.
bazel query 'deps(//some_dir/foo:main)' --output maxrank | awk '($1 < 5) { print $2;} ' > foo bazel query "kind(cc_library, set($(<foo)))"
In these examples, $(<foo)
is a shorthand
for $(cat foo)
, but shell commands other
than cat
may be used too—such as
the previous awk
command.
Note, set()
introduces no graph ordering constraints,
so path information may be lost when saving and reloading sets of
nodes using it. See the graph order
section below for more detail.
Functions
expr ::= word '(' int | word | expr ... ')'
The query language defines several functions. The name of the function determines the number and type of arguments it requires. The following functions are available:
allpaths
attr
buildfiles
rbuildfiles
deps
filter
kind
labels
loadfiles
rdeps
allrdeps
same_pkg_direct_rdeps
siblings
some
somepath
tests
visible
Transitive closure of dependencies: deps
expr ::= deps(expr) | deps(expr, depth)
The deps(x)
operator evaluates to the graph
formed by the transitive closure of dependencies of its argument set
x. For example, the value of deps(//foo)
is
the dependency graph rooted at the single node foo
,
including all its dependencies. The value of
deps(foo/...)
is the dependency graphs whose roots are
all rules in every package beneath the foo
directory.
Please note that 'dependencies' means only rule and file targets
in this context, therefore the BUILD and Skylark files needed to
create these targets are not included here. For that you should use the
buildfiles
operator.
The resulting graph is ordered according to the dependency relation. See the section on graph order for more details.
The deps
operator accepts an optional second argument,
which is an integer literal specifying an upper bound on the depth
of the search. So deps(foo:*, 1)
evaluates to all the
direct prerequisites of any target in the foo
package,
and deps(foo:*, 2)
further includes the nodes directly
reachable from the nodes in deps(foo:*, 1)
, and so on.
(These numbers correspond to the ranks shown in
the minrank
output
format.) If the depth parameter is omitted, the search
is unbounded, i.e. it computes the reflexive transitive closure of
prerequsites.
Transitive closure of reverse dependencies: rdeps
expr ::= rdeps(expr, expr) | rdeps(expr, expr, depth)
The rdeps(u, x)
operator evaluates
to the reverse dependencies of the argument set x within the
transitive closure of the universe set u.
The resulting graph is ordered according to the dependency relation. See the section on graph order for more details.
The rdeps
operator accepts an optional third argument,
which is an integer literal specifying an upper bound on the depth of the
search. The resulting graph will only include nodes within a distance of the
specified depth from any node in the argument set. So
rdeps(//foo, //common, 1)
evaluates to all nodes in the
transitive closure of //foo
that directly depend on
//common
. (These numbers correspond to the ranks shown in the
minrank
output format.) If the
depth parameter is omitted, the search is unbounded.
Transitive closure of all reverse dependencies: allrdeps
expr ::= allrdeps(expr) | allrdeps(expr, depth)Only available with Sky Query
The allrdeps
operator behaves just like the rdeps
operator, except that the "universe set" is whatever the --universe_scope
flag
evaluated to, instead of being separately specified. Thus, if
--universe_scope=//foo/...
was passed, then allrdeps(//bar)
is
equivalent to rdeps(//foo/..., //bar)
.
Direct reverse dependencies in the same package: same_pkg_direct_rdeps
expr ::= same_pkg_direct_rdeps(expr)
The same_pkg_direct_rdeps(x)
operator evalutes to the full set of targets
that are in the same package as a target in the argument set, and which directly depend on it.
Dealing with a target's package: siblings
expr ::= siblings(expr)
The siblings(x)
operator evalutes to the full set of targets that are in
the same package as a target in the argument set.
Arbitrary choice: some
expr ::= some(expr)
The some(x)
operator selects one target
arbitrarily from its argument set x, and evaluates to a
singleton set containing only that target. For example, the
expression some(//foo:main union //bar:baz)
evaluates to a set containing either //foo:main
or
//bar:baz
—though which one is not defined.
If the argument is a singleton, then some
computes the identity function: some(//foo:main)
is
equivalent to //foo:main
.
It is an error if the specified argument set is empty, as in the
expression some(//foo:main intersect //bar:baz)
.
Path operators: somepath, allpaths
expr ::= somepath(expr, expr) | allpaths(expr, expr)
The somepath(S, E)
and
allpaths(S, E)
operators compute
paths between two sets of targets. Both queries accept two
arguments, a set S of starting points and a set
E of ending points. somepath
returns the
graph of nodes on some arbitrary path from a target in
S to a target in E; allpaths
returns the graph of nodes on all paths from any target in
S to any target in E.
The resulting graphs are ordered according to the dependency relation. See the section on graph order for more details.
|
|
|
Target kind filtering: kind
expr ::= kind(word, expr)
The kind(pattern, input)
operator
applies a filter to a set of targets, and discards those targets
that are not of the expected kind. The pattern parameter specifies
what kind of target to match.
- file patterns can be one of:
source file
generated file
- rule patterns can be one of:
ruletype rule
ruletype
Where ruletype is a build rule. The difference between these forms is that including "rule" causes the regular expression match for ruletype to be anchored.
- package group patterns should simply be:
package group
For example, the kinds for the four targets defined by the BUILD file
(for package p
) shown below are illustrated in the
table:
genrule( name = "a", srcs = ["a.in"], outs = ["a.out"], cmd = "...", ) |
|
Thus, kind("cc_.* rule", foo/...)
evaluates to the set
of all cc_library
, cc_binary
, etc,
rule targets beneath
foo
, and kind("source file", deps(//foo))
evaluates to the set of all source files in the transitive closure
of dependencies of the //foo
target.
Quotation of the pattern argument is often required
because without it, many regular expressions, such as source
file
and .*_test
, are not considered words by
the parser.
When matching for package group
, targets ending in
:all
may not yield any results.
Use :all-targets
instead.
Target name filtering: filter
expr ::= filter(word, expr)
The filter(pattern, input)
operator
applies a filter to a set of targets, and discards targets whose
labels (in absolute form) do not match the pattern; it
evaluates to a subset of its input.
The first argument, pattern is a word containing a
regular expression over target names. A filter
expression
evaluates to the set containing all targets x such that
x is a member of the set input and the
label (in absolute form, e.g. //foo:bar
)
of x contains an (unanchored) match
for the regular expression pattern. Since all
target names start with //
, it may be used as an alternative
to the ^
regular expression anchor.
This operator often provides a much faster and more robust alternative to the
intersect
operator. For example, in order to see all
bar
dependencies of the //foo:foo
target, one could
evaluate
deps(//foo) intersect //bar/...
This statement, however, will require parsing of all BUILD files in the
bar
tree, which will be slow and prone to errors in
irrelevant BUILD files. An alternative would be:
filter(//bar, deps(//foo))
which would first calculate the set of //foo
dependencies and
then would filter only targets matching the provided pattern—in other
words, targets with names containing //bar
as a
substring.
Another common use of the filter(pattern,
expr)
operator is to filter specific files by their
name or extension. For example,
filter("\.cc$", deps(//foo))
will provide a list of all .cc
files used to build
//foo
.
Rule attribute filtering: attr
expr ::= attr(word, word, expr)
The attr(name, pattern, input)
operator applies a filter to a set of targets, and discards targets that
are not rules, rule targets that do not have attribute name
defined or rule targets where the attribute value does not match the provided
regular expression pattern; it evaluates to a subset of its input.
The first argument, name is the name of the rule attribute that
should be matched against the provided regular expression pattern. The second
argument, pattern is a regular expression over the attribute
values. An attr
expression evaluates to the set containing all
targets x such that x is a member of the set
input, is a rule with the defined attribute name and
the attribute value contains an (unanchored) match for the regular expression
pattern. Please note, that if name is an optional
attribute and rule does not specify it explicitly then default attribute
value will be used for comparison. For example,
attr(linkshared, 0, deps(//foo))
will select all //foo
dependencies that are allowed to have a
linkshared attribute (e.g., cc_binary
rule) and have it either
explicitly set to 0 or do not set it at all but default value is 0 (e.g. for
cc_binary
rules).
List-type attributes (such as srcs
, data
, etc) are
converted to strings of the form [value1, ..., valuen]
,
starting with a [
bracket, ending with a ]
bracket
and using ",
" (comma, space) to delimit multiple values.
Labels are converted to strings by using the absolute form of the
label. For example, an attribute deps=[":foo",
"//otherpkg:bar", "wiz"]
would be converted to the
string [//thispkg:foo, //otherpkg:bar, //thispkg:wiz]
.
Brackets
are always present, so the empty list would use string value []
for matching purposes. For example,
attr("srcs", "\[\]", deps(//foo))
will select all rules among //foo
dependencies that have an
empty srcs
attribute, while
attr("data", ".{3,}", deps(//foo))
will select all rules among //foo
dependencies that specify at
least one value in the data
attribute (every label is at least
3 characters long due to the //
and :
).
Rule visibility filtering: visible
expr ::= visible(expr, expr)
The visible(predicate, input)
operator
applies a filter to a set of targets, and discards targets without the
required visibility.
The first argument, predicate, is a set of targets that all targets in the output must be visible to. A visible expression evaluates to the set containing all targets x such that x is a member of the set input, and for all targets y in predicate x is visible to y. For example:
visible(//foo, //bar:*)
will select all targets in the package //bar
that //foo
can depend on without violating visibility restrictions.
Evaluation of rule attributes of type label: labels
expr ::= labels(word, expr)
The labels(attr_name, inputs)
operator returns the set of targets specified in the
attribute attr_name of type "label" or "list of label" in
some rule in set inputs.
For example, labels(srcs, //foo)
returns the set of
targets appearing in the srcs
attribute of
the //foo
rule. If there are multiple rules
with srcs
attributes in the inputs set, the
union of their srcs
is returned.
Expand and filter test_suites: tests
expr ::= tests(expr)
The tests(x)
operator returns the set of all test
rules in set x, expanding any test_suite
rules into
the set of individual tests that they refer to, and applying filtering by
tag
and size
.
By default, query evaluation
ignores any non-test targets in all test_suite
rules. This can be
changed to errors with the --strict_test_suite
option.
For example, the query kind(test, foo:*)
lists all
the *_test
and test_suite
rules
in the foo
package. All the results are (by
definition) members of the foo
package. In contrast,
the query tests(foo:*)
will return all of the
individual tests that would be executed by bazel test
foo:*
: this may include tests belonging to other packages,
that are referenced directly or indirectly
via test_suite
rules.
Package definition files: buildfiles
expr ::= buildfiles(expr)
The buildfiles(x)
operator returns the set
of files that define the packages of each target in
set x; in other words, for each package, its BUILD file,
plus any files it references via load
. Note that this also returns the BUILD files
of the packages containing these load
ed files.
This operator is typically used when determining what files or
packages are required to build a specified target, often in conjunction with
the --output package
option, below). For example,
bazel query 'buildfiles(deps(//foo))' --output package
returns the set of all packages on which //foo
transitively
depends.
(Note: a naive attempt at the above query would omit
the buildfiles
operator and use only deps
,
but this yields an incorrect result: while the result contains the
majority of needed packages, those packages that contain only files
that are load()
'ed will be missing.
Package definition files: rbuildfiles
expr ::= rbuildfiles(word, ...)Only available with Sky Query
The rbuildfiles
operator takes a comma-separated list of path fragments and returns
the set of BUILD files that transitively depend on these path fragments. For instance, if
//foo
is a package, then rbuildfiles(foo/BUILD)
will return the
//foo:BUILD
target. If the foo/BUILD
file has
load('//bar:file.bzl'...
in it, then rbuildfiles(bar/file.bzl)
will
return the //foo:BUILD
target, as well as the targets for any other BUILD files that
load //bar:file.bzl
The scope of the --universe_scope
flag. Files that do not correspond directly to BUILD files and .bzl
files do not affect the results. For instance, source files (like foo.cc
) are ignored,
even if they are explicitly mentioned in the BUILD file. Symlinks, however, are respected, so that
if foo/BUILD
is a symlink to bar/BUILD
, then
rbuildfiles(bar/BUILD)
will include //foo:BUILD
in its results.
The rbuildfiles
operator is almost morally the inverse of the
buildfiles
operator. However, this moral inversion
holds more strongly in one direction: the outputs of rbuildfiles
are just like the
inputs of buildfiles
; the former will only contain BUILD file targets in packages,
and the latter may contain such targets. In the other direction, the correspondence is weaker. The
outputs of the buildfiles
operator are targets corresponding to all packages and .bzl
files needed by a given input. However, the inputs of the rbuildfiles
operator are
not those targets, but rather the path fragments that correspond to those targets.
Package definition files: loadfiles
expr ::= loadfiles(expr)
The loadfiles(x)
operator returns the set of
Skylark files that are needed to load the packages of each target in
set x. In other words, for each package, it returns the
.bzl files that are referenced from its BUILD files.
Output Formats
bazel query
generates a graph.
You specify the content, format, and ordering by which
bazel query
presents this graph
by means of the --output
command-line option.
When running with Sky Query, only output formats that are compatible with
unordered output are allowed. Specifically, graph
, minrank
, and
maxrank
output formats are forbidden.
Some of the output formats accept additional options. The name of
each output option is prefixed with the output format to which it
applies, so --graph:factored
applies only
when --output=graph
is being used; it has no effect if
an output format other than graph
is used. Similarly,
--xml:line_numbers
applies only when --output=xml
is being used.
On the ordering of results
Although query expressions always follow the "law of
conservation of graph order", presenting the results may be done
in either a dependency-ordered or unordered manner. This does not
influence the targets in the result set or how the query is computed. It only
affects how the results are printed to stdout. Moreover, nodes that are
equivalent in the dependency order may or may not be ordered alphabetically.
The --order_output
flag can be used to control this behavior.
(The --[no]order_results
flag has a subset of the functionality
of the --order_output
flag and is deprecated.)
The default value of this flag is auto
, which is equivalent to
full
for every output format except for proto
,
graph
, minrank
, and maxrank
, for which
it is equivalent to deps
.
When this flag is no
and --output
is one of
build
, label
, label_kind
,
location
, package
, proto
,
record
or xml
, the outputs will be printed in
arbitrary order. This is generally the fastest option. It is not
supported though when --output
is one of graph
,
minrank
or maxrank
: with these formats, bazel will
always print results ordered by the dependency order or rank.
When this flag is deps
, bazel will print results ordered by the
dependency order. However, nodes that are unordered by the dependency order
(because there is no path from either one to the other) may be printed in any
order.
When this flag is full
, bazel will print results ordered by the
dependency order, with unordered nodes ordered alphabetically or reverse
alphabetically, depending on the output format. This may be slower than the
other options, and so should only be used when deterministic results are
important — it is guaranteed with this option that running the same query
multiple times will always produce the same output.
Print the source form of targets as they would appear in BUILD
--output build
With this option, the representation of each target is as if it were
hand-written in the BUILD language. All variables and function calls
(e.g. glob, macros) are expanded, which is useful for seeing the effect
of Skylark macros. Additionally, each effective rule is annotated with
the name of the macro (if any, see generator_name
and
generator_function
) that produced it.
Although the output uses the same syntax as BUILD files, it is not guaranteed to produce a valid BUILD file.
Print the label of each target
--output label
With this option, the set of names (or labels) of each target
in the resulting graph is printed, one label per line, in
topological order (unless --noorder_results
is specified, see
notes on the ordering of results).
(A topological ordering is one in which a graph
node appears earlier than all of its successors.) Of course there
are many possible topological orderings of a graph (reverse
postorder is just one); which one is chosen is not specified.
When printing the output of a somepath
query, the order
in which the nodes are printed is the order of the path.
Caveat: in some corner cases, there may be two distinct targets with
the same label; for example, a sh_binary
rule and its
sole (implicit) srcs
file may both be called
foo.sh
. If the result of a query contains both of
these targets, the output (in label
format) will appear
to contain a duplicate. When using the label_kind
(see
below) format, the distinction becomes clear: the two targets have
the same name, but one has kind sh_binary rule
and the
other kind source file
.
Print the label and kind of each target
--output label_kind
Like label
, this output format prints the labels of
each target in the resulting graph, in topological order, but it
additionally precedes the label by
the kind of the target.
Print the label of each target, in rank order
--output minrank --output maxrank
Like label
, the minrank
and maxrank
output formats print the labels of each
target in the resulting graph, but instead of appearing in
topological order, they appear in rank order, preceded by their
rank number. These are unaffected by the result ordering
--[no]order_results
flag (see notes on
the ordering of results).
There are two variants of this format: minrank
ranks
each node by the length of the shortest path from a root node to it.
"Root" nodes (those which have no incoming edges) are of rank 0,
their successors are of rank 1, etc. (As always, edges point from a
target to its prerequisites: the targets it depends upon.)
maxrank
ranks each node by the length of the longest
path from a root node to it. Again, "roots" have rank 0, all other
nodes have a rank which is one greater than the maximum rank of all
their predecessors.
All nodes in a cycle are considered of equal rank. (Most graphs are acyclic, but cycles do occur simply because BUILD files contain erroneous cycles.)
These output formats are useful for discovering how deep a graph is.
If used for the result of a deps(x)
, rdeps(x)
,
or allpaths
query, then the rank number is equal to the
length of the shortest (with minrank
) or longest
(with maxrank
) path from x
to a node in
that rank. maxrank
can be used to determine the
longest sequence of build steps required to build a target.
Please note, the ranked output of a somepath
query is
basically meaningless because somepath
doesn't
guarantee to return either a shortest or a longest path, and it may
include "transitive" edges from one path node to another that are
not direct edges in original graph.
For example, the graph on the left yields the outputs on the right
when --output minrank
and --output maxrank
are specified, respectively.
minrank 0 //c:c 1 //b:b 1 //a:a 2 //b:b.cc 2 //a:a.cc |
maxrank 0 //c:c 1 //b:b 2 //a:a 2 //b:b.cc 3 //a:a.cc |
Print the location of each target
--output location
Like label_kind
, this option prints out, for each
target in the result, the target's kind and label, but it is
prefixed by a string describing the location of that target, as a
filename and line number. The format resembles the output of
grep
. Thus, tools that can parse the latter (such as Emacs
or vi) can also use the query output to step through a series of
matches, allowing the Bazel query tool to be used as a
dependency-graph-aware "grep for BUILD files".
The location information varies by target kind (see the kind operator). For rules, the location of the rule's declaration within the BUILD file is printed. For source files, the location of line 1 of the actual file is printed. For a generated file, the location of the rule that generates it is printed. (The query tool does not have sufficient information to find the actual location of the generated file, and in any case, it might not exist if a build has not yet been performed.)
Print the set of packages
--output package
This option prints the name of all packages to which some target in the result set belongs. The names are printed in lexicographical order; duplicates are excluded. Formally, this is a projection from the set of labels (package, target) onto packages.
Packages in external repositories are formatted as
@repo//foo/bar
while packages in the main repository are
formatted as foo/bar
.
In conjunction with the deps(...)
query, this output
option can be used to find the set of packages that must be checked
out in order to build a given set of targets.
Display a graph of the result
--output graph
This option causes the query result to be printed as a directed
graph in the popular AT&T GraphViz format. Typically the
result is saved to a file, such as .png
or .svg
.
(If the dot
program is not installed on your workstation, you
can install it using the command sudo apt-get install graphviz
.)
See the example section below for a sample invocation.
This output format is particularly useful for allpaths
,
deps
, or rdeps
queries, where the result
includes a set of paths that cannot be easily visualized when
rendered in a linear form, such as with --output label
.
By default, the graph is rendered in a factored form. That is,
topologically-equivalent nodes are merged together into a single
node with multiple labels. This makes the graph more compact
and readable, because typical result graphs contain highly
repetitive patterns. For example, a java_library
rule
may depend on hundreds of Java source files all generated by the
same genrule
; in the factored graph, all these files
are represented by a single node. This behavior may be disabled
with the --nograph:factored
option.
--graph:node_limit n
The option specifies the maximum length of the label string for a
graph node in the output. Longer labels will be truncated; -1
disables truncation. Due to the factored form in which graphs are
usually printed, the node labels may be very long. GraphViz cannot
handle labels exceeding 1024 characters, which is the default value
of this option. This option has no effect unless
--output=graph
is being used.
--[no]graph:factored
By default, graphs are displayed in factored form, as explained
above.
When --nograph:factored
is specified, graphs are
printed without factoring. This makes visualization using GraphViz
impractical, but the simpler format may ease processing by other
tools (e.g. grep). This option has no effect
unless --output=graph
is being used.
XML
--output xml
This option causes the resulting targets to be printed in an XML form. The output starts with an XML header such as this
<?xml version="1.0" encoding="UTF-8"?> <query version="2">
and then continues with an XML element for each target in the result graph, in topological order (unless unordered results are requested), and then finishes with a terminating
</query>
Simple entries are emitted for targets of file
kind:
<source-file name='//foo:foo_main.cc' .../> <generated-file name='//foo:libfoo.so' .../>
But for rules, the XML is structured and contains definitions of all the attributes of the rule, including those whose value was not explicitly specified in the rule's BUILD file.
Additionally, the result includes rule-input
and
rule-output
elements so that the topology of the
dependency graph can be reconstructed without having to know that,
for example, the elements of the srcs
attribute are
forward dependencies (prerequisites) and the contents of the
outs
attribute are backward dependencies (consumers).
rule-input
elements for implicit dependencies are suppressed if
--noimplicit_deps
is specified.
<rule class='cc_binary rule' name='//foo:foo' ...> <list name='srcs'> <label value='//foo:foo_main.cc'/> <label value='//foo:bar.cc'/> ... </list> <list name='deps'> <label value='//common:common'/> <label value='//collections:collections'/> ... </list> <list name='data'> ... </list> <int name='linkstatic' value='0'/> <int name='linkshared' value='0'/> <list name='licenses'/> <list name='distribs'> <distribution value="INTERNAL" /> </list> <rule-input name="//common:common" /> <rule-input name="//collections:collections" /> <rule-input name="//foo:foo_main.cc" /> <rule-input name="//foo:bar.cc" /> ... </rule>
Every XML element for a target contains a name
attribute, whose value is the target's label, and
a location
attribute, whose value is the target's
location as printed by the --output
location
.
--[no]xml:line_numbers
By default, the locations displayed in the XML output contain line numbers.
When --noxml:line_numbers
is specified, line numbers are not
printed.
--[no]xml:default_values
By default, XML output does not include rule attribute whose value is the default value for that kind of attribute (e.g. because it were not specified in the BUILD file, or the default value was provided explicitly). This option causes such attribute values to be included in the XML output.
Querying with external repositories
If the build depends on rules from external repositories (defined in the
WORKSPACE file) then query results will include these dependencies. For
example, if //foo:bar
depends on //external:some-lib
and //external:some-lib
is bound to
@other-repo//baz:lib
, then
bazel query 'deps(//foo:bar)'
will list both @other-repo//baz:lib
and
//external:some-lib
as dependencies.
External repositories themselves are not dependencies of a build. That is, in
the example above, //external:other-repo
is not a dependency. It
can be queried for as a member of the //external
package, though,
for example:
# Querying over all members of //external returns the repository. bazel query 'kind(maven_jar, //external:*)' //external:other-repo # ...but the repository is not a dependency. bazel query 'kind(maven_jar, deps(//foo:bar))' INFO: Empty results